Abstract
Streptomyces coelicolor is a model organism for the Actinobacteria, a phylum known to produce an extensive range of different bioactive compounds that include antibiotics currently used in the clinic. Biosynthetic gene clusters discovered in genomes of other Actinobacteria can be transferred to and expressed in S. coelicolor, making it a factory for heterologous production of secondary metabolites. Genome-scale metabolic reconstructions have successfully been used in several biotechnology applications to facilitate the over-production of target metabolites. Here, the authors present iKS1317, the most comprehensive and accurate reconstructed genome-scale metabolic model (GEM) for S. coelicolor. The model reconstruction is based on previous models, publicly available databases, and published literature and includes 1317 genes, 2119 reactions, and 1581 metabolites. It correctly predicts wild-type growth in 96.5% of the evaluated growth environments and gene knockout predictions in 78.4% when comparing with observed mutant growth phenotypes, with a total accuracy of 83.3%. However, using a minimal nutrient environment for the gene knockout predictions, iKS1317 has an accuracy of 87.1% in predicting mutant growth phenotypes. Furthermore, we used iKS1317 and existing strain design algorithms to suggest robust gene-knockout strategies to increase the production of acetyl-CoA. Since acetyl-CoA is the most important precursor for polyketide antibiotics, the suggested strategies may be implemented in vivo to improve the function of S. coelicolor as a heterologous expression host.
Highlights
Streptomyces coelicolor is a model organism for the Actinobacteria, a phylum global health
Since acetyl-coenzyme A (CoA) is the most important precursor for polyketide antibiotics, the suggested strategies may be implemented in vivo to improve the function of S. coelicolor as a heterologous expression host
We present iKS1317, a more validated and comprehensive genome-scale metabolic model (GEM) of S. coelicolor based on the previous model iMK1208,[18] appended and corrected with knowledge obtained from iMA789,[17] Kyoto Encyclopedia of Genes and Genomes (KEGG),[20] and BioCyc.[21]
Summary
The corresponding released tRNA molecules were added as products to balance the equation, and we adjusted the stochiometric coefficients of ATP, ADP, water, protons, and phosphate to account for the energy consumed by the reactions charging the amino acids with tRNA molecules. The content of both biomass reactions is given in S2, Supporting information. By using the excellent review of the biosynthetic pathways in S. coelicolor by Challis,[11] we added pathways for three secondary metabolites (geosmin, albaflavenon, methylenomycin) and extended the undecylprodigiosin pathway to include streptorubin Most of these reactions were described in BioCyc.[21]. S. coelicolor is supposed to take up sucrose to balance the osmotic pressure (Bibb, 1985, as cited by Elibol, 1998).[35,36] To avoid this erroneous in silico prediction, the uptake reaction rate for the sucrose-transport reaction was set to zero
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